Polish J. of Environ. Stud. Vol. 15, No. 6 (2006), 943-946 Letter to Editor Heavy Metals in Fly Ash from a Coal-Fired Power Station in Poland D. Smołka-Danielowska university of Silesia, Faculty of earth Sciences, ul.Będzińska 60, 41-200 Sosnowiec, Poland Received: January 30, 2006 Accepted: July 28, 2006 Abstract The main subject of this study is fly ash created during coal combustion in Rybnik Power Station in Upper Silesia in the southern part of Poland. This is the biggest block power station in this region. Gener- ated power is 1600 MW. Annual dust emission from professional energy in Upper Silesia is estimated at 32.8 thousand tons, which is about 22% of total national emissions. X-ray powder diffraction, Analytic Scanning Electron Microscopy (ASEM) and Induced Couple Mass Spectrometry (ICP- MS) methods have been applied extensively to heavy metals (Cu, Ni, Pb, Zn, Cr, Cd) content analysis and their host mineral phases identification. Concentrations of Cu, Ni, Pb, Zn, Cr and Cd as well as mineral composition of fly ash being their carriers have been specified.�������������������������������������������������������������������� Average Zn concentrations in fly ash are 120 ppm, but for all other elements the averege concentrations were 38 ppm for Cu, 41 ppm for Ni, 44 ppm for Pb, 64 ppm for Cr and 3 ppm for Cd. Amorphic aluminosilicate substances, oxides and sulphides are mineral phases containing heavy metals. The sizes of these particles are up to 12 µm. Keywords: power station, fly ash, heavy metals Introduction fine dispersive dust and their various chemical composi- tions determines the toxic properties of air. The smallest Upper Silesia is one of the most polluted areas of Po- particles of fly ash are enriched with heavy metals [4-8]. land. Dust emissions from professional energy of this re- An indicator of heavy metal emissions from coal com- gion constitutes 22% of total dust emission in Poland [1]. bustion processes is the specified condition of ash emis- Furnace wastes like fly ash and slugs are created in the sion indicator. This is a result of comparison between process of coal combustion in power plants. Fly ash from the amount of coal used (56 million tons per year) [3] dusty furnaces amounts to about 70-85% of grate mass of for energy production in Poland and poorly satisfying furnace wastes [2]. electro filters with high and average average efficiency of dust-collecting devices, mainly in efficiency are used for reduction of ash pollution in Polish towns boiler rooms and in heat-generating plants. Power power stations. stations have the smallest contribution to national heavy Emission of dust wastes in Upper Silesia in 2004 was metal emissions in spite of using the largest amount of 32.8 thousand tons, which is 22% of total dust emission coal. Fly ash emitted from professional industry are in Poland [3]. very small particles (<1 �������������μ������������m), which in mostly spherical and their diameters are up to 2 microm- small amounts are caught by electro filters while in ma- eters [9]. jority penetrate the atmosphere, are most important for Fly ash is a potential source of pollution not only for environmental preservation. The physical properties of the atmosphere but also for the other components of the environment. Their deposition in storage places can have *corresponding author; e-mail: [email protected] negative influences on water and soil because of their 944 Smołka-Danielowska D. granulometric and mineral composition as well grain gas desulphurization (desulphurization efficiency was morphology and filtration properties. 70-85%). The process applying cold ash reaction oc- Studies have revealed that dusts from industry have curs in the reactor at 80–130°C. It comes from the elec- greater ability to developing allergic diseases than trofilter area where there is the highest calcium oxide natural ones [10]. Additionally, they have negative in- concentration. The reaction is activated by introducing fluence on plants – mainly forests [1-11]. they show material containing base compounds with the addition a harmful influence on flora, mainly forests, choking of calcium and sodium hydroxides together with water stomatal apparatuses of plants, impeding photosynthe- from the skimming system.The studied samples have sis by sunlight screening and, as a result, decreasing been collected directly from under electro filter fun- CO2 assimilation. Atmospheric pollution related to dust nels during 2003-04. we analyzed 25 samples of fly emission caused by coal combustion and secondary ash together. dusting from waste dumps results in human and ani- Analysis have been performed using analytical scan- mal illnesses. Epidemiologists indicate a relationship ning electron microscopy method with scanning electron between high concentrations of atmospheric pollution microscopes PHILIPS XL 30 TMP, JEOL JSM-5410 and morbidity of such illnesses as chronic bronchitis equipped with edS and unified with noran instruments and lung cancer. software and HITACHI S-4700 with NORAN Vantage microanalytic system (Laboratory of Scanning Micros- copy, Jagiellonian University in Cracow) under analyti- Methods cal conditions such as acceleration voltage 20-25 kV and beam current intensity 20 nA. Analyses����������������������� were performed Samples of fly ash come from coal combustion in on carbon rings and polished pellets (the samples were Rybnik Power Station (Poland), whose power is 1600 mounted in epoxy resin). MW (8 blocks, 200MW each). Annual coal consumption the fly ash phase composition was examined by a is over 3.6 million tons. The power station is equipped PHILIPS PW 3710 X-ray diffractometer. The following for fume desulphatization and electrofilters. Flying ash measurement conditions have been applied: lamp volt- was sampled in the process of semi-arid combustion age – 45 kV, current intensity – 30 mA, time of impulses Fig. 1. SeM image with edS spectrum of ni, cu and zn oxides in fly ash from rybnik Power Station. Fig. 2. SeM image with edS spectrum of PbS in fly ash from rybnik Power Station. Heavy Metals in Fly... 945 counting in the step method was 2 and 3 second (per a point to the dominant role of anthropogenic components step), counter speed was 0.010 and 0.020 per minute. The [1]. The most important sources of tropospheric pollution estimated concentrations (%) of the analyzed mineral are not the factories of professional industry but ash from components are given using the X’PERT computer pro- so-called low emissions, that come from coal combustion gram. in home fireplaces and boiler rooms of housing estates Contents of trace elements have been established by that do not possess any facilities for reduction of dusty ICP and ICP-MS methods using JARRELL ASH Envi- and gaseous pollution. ro model and PERKIN ELMER spectrometers in Acti- vation Laboratories Ltd., Canada. �������������������Determinations were performed dissolving flying ash. to this aim a 0.25g Summary sample was dissolved in 10 ml HCl-HNO3- HClO4- hF at 200°c, and next the extracts were filled up to results of studies confirm the pro-ecological activi- 10 ml with diluted aqua regia�������������������������trace. The instrument op- ties conducted by Rybnik Power Station in the vicinity of erated by inductively coupled plasma mass spectrom- burned coal quality improvement and the technology of etry (ICP-MS): Rf power 900 w, argon plasma flow 16 this process. l/min, argon nebulizer flow 0.8 l/min, argon auxiliary The average concentration of Ni, Cu and Pb in ana- flow 0.7 l/min. lyzed samples of fly ash does not exceed 45 ppm. ox- ides, aluminosilicatic substance, sulphides and chlorides (Pb mainly) play the role of heavy metal carriers. The Results and Discussion sizes of single particles and aggregates do not exceed 2 and 12 μm, respectively. cu, ni and zn occur within The share of particular trace elements is pretty much aluminosilicatic and oxide linkage, but Pb most often on the same level of concentration (Cu – 55ppm, Ni –78 occur as sulphides and chlorides. However, the amor- ppm, Pb – 67 ppm). However, the maximal concentra- phic phases in fly ash, which amount to 70 wt%, are far tions have been obtained for zinc (120 ppm) and those easier solved than the crystal substance with the same concentrations are in agreement with published results of composition. It is necessary to pay particular attention fly ash studies conducted by different authors in different to this process mainly in the case of fly ash deposition in scientific centres [12-14]. disposal places. The average concentration of Cu, Ni, Pb and Zn de- termined in coal burned in the Rybnik Power Station is lower than that from fly ash and is equal to 24g/t (cu), References 24 g/t (Ni), 18 g/t (Pb), 45 g/t (Zn), 38 g/t (Cr) and 5 g/t (Cd). 1. JABŁońSkA M. Phase composition of atmospheric dust The applied methods of studying allowed determina- from selected cities of the Upper Silesia Industrial Region. tion of the mineral composition of the fly ash particles wyd. uŚ., katowice, 2003. which are the heavy metal carriers. Cu, Zn, Pb and Ni 2. lAudyn d, PAwlik M., Strzelczyk F. Power plants. oxides have been identified (Fig. 1). lead sulphates and Wyd. Nauk. Techn., Warszawa, 2000. (In Polish) chlorides (Fig. 2) as well as aluminosilicate phase con- 3. GŁÓwny urzĄd StAtyStyczny. Statistical year- taining varied amounts of Cu, Ni, Pb and Zn have been book, Warszawa, 2004. (In Polish) determined. The aluminosilicate particles have an amor- 4. FulekAr M.h., dAve J.M. diposal of fly ash – an envi- phic character confirmed by X-ray studies. ronmental problem. International Journal of Environmental Fly ash difractograms had high background and a Studies, 26, 191, 1986. “hump” characteristic for amorphic substance in the 5. ��������������������������������������������������QUEROL X., FERNANDEZ T.J.L., LOPEZ S.A.
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